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The Journal of Neuroscience, August 15, 1999, 19(16):6806-6817
Biphasic, Opposing Modulation of Cloned Neuronal 
1E Ca
Channels by Distinct Signaling Pathways Coupled to M2 Muscarinic
Acetylcholine Receptors
Ulises
Meza,
Roger
Bannister,
Karim
Melliti, and
Brett
Adams
Department of Physiology and Biophysics, University of Iowa,
College of Medicine, Iowa City, Iowa 52242-1109
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ABSTRACT |
Neuronal 
1E subunits are thought to form R-type Ca channels.
When expressed in human embryonic kidney cells with M2
muscarinic acetylcholine receptors, Ca channels encoded by rabbit 1E
exhibit striking biphasic modulation. Receptor activation first
produces rapid inhibition of current amplitude and activation rate.
However, in the continued presence of agonist, 1E currents
subsequently increase. Kinetic slowing persists during this secondary
stimulation phase. After receptor deactivation, kinetic slowing is
quickly relieved, and current amplitude over-recovers before returning toward control levels. These features indicate that inhibition and
stimulation of 1E are separate processes, with stimulation superimposed on inhibition. Pertussis toxin eliminates inhibition without affecting stimulation, demonstrating that inhibition and stimulation involve distinct signaling pathways. Neither inhibition nor
stimulation is altered by coexpression of Ca channel 
2a or 3
subunits. Stimulation is abolished by staurosporine and reduced by
intracellular 5'-adenylylimidodiphosphate, suggesting that phosphorylation is required. However, stimulation does not seem to
involve cAMP-dependent protein kinase, protein kinase C, cGMP-dependent protein kinase, tyrosine kinases, or phosphoinositide 3-kinases. Stimulation does not require a Ca signal, because it is not
specifically altered by varying intracellular Ca buffering or by
substituting Ba as the charge carrier. In contrast to those formed by
1E, Ca channels formed by 1A or 1B display only inhibition and
no stimulation during prolonged activation of M2 receptors. The dual modulation of 1E may confer unique physiological properties on native R-type Ca channels. As one possibility, R-type channels may
continue to mediate Ca influx during steady inhibition of N-type and
P/Q-type channels by muscarinic or other receptors.
Key words:
1A; 1B; R-type Ca channel; G-protein; ion channel
modulation; neurosecretion; presynaptic inhibition; neuronal
integration; HEK293 cells; electrophysiology; patch-clamp recording; phosphorylation; protein kinases
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INTRODUCTION |
Ca influx through voltage-gated Ca
channels triggers neurosecretion and influences neuronal membrane
excitability, gene expression, and developmental events. Neurons
express several different kinds of voltage-gated Ca channels, which are
classified according to the primary structure of their pore-forming
(1) subunits. Class E (1E) subunits are widely expressed in brain
(Niidome et al., 1992
; Soong et al., 1993; Wakamori et al., 1994;
Yokoyama et al., 1995) and appear to localize primarily to neuronal
soma and dendrites (Yokoyama et al., 1995; Westenbroek et al., 1998).
Recent experiments indicate that 1E forms native "R-type" Ca
channels in rat cerebellar granule neurons (Piedras-Rentería
and Tsien, 1998). R-type channels are so named because they are
resistant to known, selective Ca channel blockers (Randall and Tsien,
1995). Although the physiological functions of R-type Ca channels are
mostly unknown, available evidence indicates that they contribute to
neurotransmitter secretion at some central synapses (Turner et al.,
1995; Wu et al., 1998) and to hormone secretion by certain types of
neuroendocrine cells (Wang et al., 1998).
The functional activity of neuronal, high-voltage-activated Ca
channels is controlled by biochemical cascades involving heterotrimeric G-proteins (Hille, 1994). Typically, activation of G-protein-coupled receptors produces inhibition of neuronal Ca channels. Inhibition can
occur via membrane-delimited and/or cytoplasmic signaling pathways, and
inhibition may be voltage dependent (Bean, 1989) or voltage independent
(Luebke and Dunlap, 1994). Membrane-delimited, voltage-dependent
inhibition of mammalian neuronal Ca channels seems to be mediated by
G-protein 
subunits [Herlitze et al. (1996); Ikeda (1996); but
see Diversé-Pierluissi et al. (1997) regarding avian channels].
In the currently accepted hypothesis, certain G subunits interact
directly with certain Ca channel 1 subunits. Recent studies have
sought to identify structural regions of 1 involved in binding
G; the results indicate that G can bind the intracellular
I-II loop (De Waard et al., 1997; Zamponi et al., 1997; García
et al., 1998b), the C terminal (Qin et al., 1997), and the N terminal
(Page et al., 1998) of 1A, 1B, and 1E. On the single-channel
level, G binding increases the first latency of channel opening,
at least for N-type Ca channels (Carabelli et al., 1996; Patil et al.,
1996).
Although cloned 1E and native R-type Ca channels are significantly
modulated via G-protein-dependent pathways (Yassin et al., 1996; Jeong
and Wurster, 1997; Qin et al., 1997; Meza and Adams, 1998; Page et al.,
1998), the details of their modulation are unclear in comparison with
the more extensively studied N-type and P/Q-type Ca channels (Jones and
Elmslie, 1997). In this paper we report intriguing new findings
concerning the receptor-mediated modulation of cloned 1E Ca
channels. We show that sustained activation of M2 muscarinic receptors
produces first inhibition and then stimulation of Ca channels encoded
by 1E. Inhibition and stimulation are separate events, with
stimulation superimposed on inhibition. Our results demonstrate that
inhibition and stimulation result from distinct signaling pathways that
couple to M2 receptors. The dual modulation of 1E may have important
implications for the biological functions of native R-type Ca channels.
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MATERIALS AND METHODS |
Cell culture and transfection. Human embryonic kidney
(HEK293) cells were maintained at 37°C in a humidified atmosphere of 95% O2 and 5% CO2. The
culture medium contained 90% DMEM, 10% fetal bovine serum, and 50 µg/ml gentamycin. Every 2-3 d, the cells were briefly trypsinized
and replated onto 12 mm round glass coverslips in 35 mm plastic culture
dishes. Approximately 15 hr later, these replated cells were
transfected via CaPO4 precipitation with
expression plasmids encoding 1E (rabbit brain; accession number
X67856) (Niidome et al., 1992), 1A (rabbit brain; accession number
X57477) (Mori et al., 1991), or 1B (rabbit brain; accession number
D14157) (Fujita et al., 1993) Ca channel subunits at 1 µg per 35 mm
culture dish. Unless noted, the transfection mixture also contained
plasmids encoding Ca channel 2 (rat brain; accession number M86621)
(Kim et al., 1992) and 3 (rabbit brain; accession number X64300)
(Witcher et al., 1993) subunits at 1 µg per dish. In selected
experiments the subunit was omitted, or 2a (rat brain; accession
number M80545) (Perez-Reyes et al., 1992) was used instead of 3.
Transfection mixtures also included plasmids encoding the M2 muscarinic
acetylcholine receptor (human; accession number X15264) (Peralta et
al., 1987) at 0.05 µg of cDNA per dish (unless noted otherwise) and
enhanced green fluorescent protein (jellyfish; accession number U55607;
Clontech, Cambridge, UK) at 0.1 µg per dish. Successfully transfected
cells were visually identified by their green fluorescence under
ultraviolet illumination. Only green cells were used for
electrophysiological experiments.
Expression plasmids. 1E was in the expression vector
pcDNA3.1+ neo (Invitrogen, San Diego, CA). 1A and 1B were in
pKCRH2 (Mishina et al., 1984); 2 was in pMT2 (Genetics Institute,
Cambridge, MA); 3 was in pcDNA3 (Invitrogen); 2a was in
p91023(b); the M2 receptor was in pRK5; and enhanced green fluorescent
protein (EGFP) was in pEGFP-C3 (Clontech).
Voltage-clamp recordings. Large-bore patch pipettes were
pulled from 100 µl borosilicate glass micropipettes (VWR Scientific) and filled with an intracellular solution containing (in
mM): 155 CsCl, 10 Cs2EGTA, 4 MgATP,
0.32 TrisGTP, and 10 HEPES, pH 7.4 with CsOH. In selected experiments,
Cs2EGTA was reduced to 0.1 mM or was
replaced by either 0.1 or 20 mM
Cs4BAPTA. In some experiments, the pipette
solution contained 20 mM BAPTA plus 10 mM
CaCl2. Aliquots of pipette solutions were stored
at 
80°C, kept on ice after thawing, and filtered at 0.22 µm
immediately before use. Pipette tips were dipped in molten paraffin to
reduce capacitance and then fire-polished. Filled pipettes had DC
resistances of 1.0-1.5 M
. The bath solution contained (in
mM): 145 NaCl, 40 CaCl2, 2 KCl, and
10 HEPES, pH 7.4 with NaOH. After a gigaohm seal was formed, the
residual pipette capacitance was compensated in the cell-attached
configuration using the negative capacitance circuit of the patch-clamp
amplifier. Ca currents were recorded using the whole-cell technique
(Hamill et al., 1981). The steady holding potential was 90 mV. Test
depolarizations were delivered every 1-15 sec; the stimulation rate
was adjusted for individual cells to maximize sampling rate while
minimizing cumulative inactivation. To minimize inactivation further,
brief (5-10 msec for 1E currents) test depolarizations were used.
Currents were filtered at 2-10 kHz using the built-in Bessel filter
(four-pole low-pass) of an Axopatch 200A or 200B amplifier and sampled
at 10-50 kHz using a Digidata 1200 analog-to-digital board installed
in a Gateway 486 or Pentium I computer. The pCLAMP software programs
Clampex and Clampfit (version 6.0.3) were used for data acquisition and analysis, respectively. Figures, linear regressions, and statistical comparisons were done using the software program Microcal Origin (version 5.0). Linear cell capacitance (C) was
determined by integrating the area under the whole-cell capacity
transient, evoked by clamping from 90 to 80 mV with the whole-cell
capacitance compensation circuit of the amplifier turned off. The
average value of C was 22 ± 1 pF (mean ± SEM;
n = 318 cells). Series resistance
(RS) was calculated as 
* (1/C), where is the
time constant for decay of the whole-cell capacity transient.
and RS were minimized using
the series resistance compensation circuit of the amplifier. The
average values of compensated and
RS were 60 ± 3 µsec and 2.8 ± 0.1 M, respectively (n = 318). Ca currents were
evoked by step depolarizations to +30 mV, which is near the peak of the current-voltage (I-V) relationship under
these ionic conditions (Meza and Adams, 1998). No corrections were made
for liquid junction potentials. Maximal currents, measured at the time
of peak inward current, were 1800 ± 100 pA (n = 318). The average maximal voltage error was 4.4 ± 0.2 mV
(n = 318). The DC resistance of the whole-cell configuration was typically >500 M. All currents were corrected for
linear capacitance and leakage currents using P/6 or P/4 subtraction. To quantify macroscopic activation rates, we fit single-exponential functions to the activating segments of individual test currents. A single-exponential function provided a
good-to-excellent fit, yielding a single time constant for activation.
Carbachol (CCh) was dissolved directly in the bath solution;
application of CCh was by bath exchange or local superfusion through a
macropipette positioned close to the cell. Temperature (20-22°C) was
continuously monitored using a miniature thermocouple placed in the
recording chamber. Statistical comparisons were made using an unpaired
t test or one-way ANOVA, as appropriate, with
p < 0.05 considered significant.
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RESULTS |
1E Ca channels exhibit biphasic, opposing modulation
Activation of M2 muscarinic acetylcholine receptors evoked a
striking biphasic response of 1E Ca channels expressed in HEK293 cells. An experiment illustrating this phenomenon is depicted in Figure
1A. Application of the
acetylcholine receptor agonist CCh (50 µM) initially caused a rapid decrease in the
macroscopic current amplitude and a slowing of activation kinetics
("inhibition"). Surprisingly, if the CCh application was
maintained, 1E current amplitudes subsequently increased
("stimulation"). Kinetic slowing persisted during this secondary
stimulation phase, as revealed by the time constants for activation
(act), which were 1.1 ± 0.04 msec
(n = 42) before exposure to CCh (Fig.
1A, point a), 1.7 ± 0.06 msec
(n = 42) at the time of maximal inhibition
(point b), and 1.6 ± 0.06 msec
(n = 42) at the time of maximal stimulation (point c). After CCh washout, current amplitudes
over-recovered beyond the initial control level (point
d), and normal activation kinetics were restored
(act = 1.1 ± 0.04 msec;
n = 38). The over-recovery after CCh washout was nearly
as large (86 ± 4%; n = 38) as the initial
inhibition measured in the same cell. After the over-recovery, current
amplitudes gradually decreased toward the control level, with an
approximately exponential time course.
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Figure 1.
Biphasic, opposing modulation of 1E Ca
channels. A, The amplitudes of 1E Ca currents
(mediated by 1E/2/3 channels) are shown plotted as a function
of time during a representative experiment. The application of CCh (50 µM) is indicated by a horizontal black
bar. Ca currents were evoked every 3 sec, using the voltage
protocol shown (top right). Ca current waveforms,
recorded at the indicated times (points
a-d), are shown to the right of the time plot.
Linear cell capacitance (C) was 23 pF; series
resistance (RS) was 2.0 M.
File 98610007. B, Rapid application of CCh reveals
distinct time courses for inhibition and stimulation. Ca currents were
evoked at 1 Hz by short (10 msec) depolarizations to +30 mV from a
holding potential of 90 mV. CCh (50 µM) was
applied through a macropipette positioned within 2-3 mm of the cell;
the perfusion apparatus allowed the medium surrounding the cell to be
exchanged completely within 1-2 sec (Melliti et al., 1999).
C = 16 pF; RS = 2.7 M. File 99414033. C, 1A Ca currents do not
exhibit stimulation. Currents mediated by 1A/2/3 were evoked
every 2 sec using the voltage protocol diagrammed in A.
C = 21 pF; RS = 4.2 M. File 98904009. D, 1B Ca currents do not exhibit
stimulation either. Currents mediated by 1B/2/3 were evoked
every 5 sec using the voltage protocol diagrammed in A.
C = 14 pF; RS = 2.5 M. File 99205010. E, Average (± SEM) inhibition and
stimulation of 1A, 1B, and 1E currents are shown. Data are
from currents evoked by depolarizations to +30 mV. Percent inhibition
(by 50 µM CCh) was calculated as the difference
between the peak amplitude of the control current (recorded directly
before CCh application) and the peak amplitude of the current during
maximal inhibition divided by the control current amplitude. Percent
stimulation was calculated as the difference between the peak current
amplitude during maximal inhibition and the peak current amplitude at
the height of stimulation divided by the control current amplitude. For
the indicated vertical bars, atropine
(+Atr; 50 µM) was present during the
application of CCh. The number of cells in each group is
given in parentheses in this and subsequent
figures.
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Two observations demonstrate that the secondary increase in 1E
current amplitude (stimulation) does not reflect the relief of
G-protein-mediated inhibition. First, kinetic slowing persisted during
the stimulation phase. Kinetic slowing is a hallmark of membrane-delimited, voltage-dependent inhibition (Luebke and Dunlap, 1994), and its presence indicates that membrane-delimited inhibition was maintained during stimulation. Second, the over-recovery of current
amplitude after CCh washout was opposite in direction, and similar in
magnitude, to that of the initial inhibition. Thus, inhibition was
present, mostly undiminished, throughout the application of CCh and was
not relieved until washout. These observations suggest that inhibition
and stimulation of 1E channels are separate events and that
stimulation is superimposed on inhibition. Consistent with this
interpretation, the time courses of inhibition and stimulation were
distinctly different (Fig. 1B). When CCh was applied
using a fast-perfusion apparatus and Ca currents were sampled at 1 Hz, inhibition could be seen to reach a stable plateau lasting several seconds before stimulation became apparent (Fig. 1B).
When we measured from the last uninhibited current before CCh
application (Fig. 1B, arrow), inhibition attained its
maximal level in 4 ± 1 sec (n = 10), whereas
stimulation required 47 ± 4 sec (n = 10) to reach
its peak. In addition to their different time courses, there was no
correlation between the magnitudes of inhibition and stimulation
measured in the same cell (linear regression correlation coefficient
r = 0.16; n = 42; p = 0.31). Together these observations suggest that inhibition and
stimulation result from separate processes.
For comparative purposes, identical experiments were performed using
1A and 1B Ca channels, which encode P/Q-type and N-type Ca
channels, respectively. As illustrated in Figure 1, C and
D, currents mediated by 1A and 1B were steadily
inhibited in the presence of CCh, and current amplitudes did not
over-recover after CCh washout. No appreciable stimulation was observed
in 11 experiments with 1A and 11 experiments with 1B. The steady
inhibition of 1A and 1B channels is important because it
demonstrates that M2 receptors did not desensitize within the time
frame of our experiments.
Figure 1E compares the average modulation of 1A,
1B, and 1E Ca channels. The percentage of current inhibited by 50 µM CCh was greatest for 1B (77 ± 3%;
n = 11), followed by 1A (53 ± 3%;
n = 11) and 1E (40 ± 1%; n = 42). Only 1E displayed significant stimulation. Both inhibition and
stimulation of 1E were blocked by the muscarinic antagonist atropine
(50 µM), confirming that both phases of
modulation were triggered via muscarinic acetylcholine receptors. CCh
had no effects in cells that had not been transfected with M2 receptors
(n = 8; data not shown), consistent with previous measurements of very low numbers (<200/cell) of endogenous muscarinic receptors in HEK293 cells (Peralta et al., 1987).
Neither inhibition nor stimulation of 1E was significantly altered
after >5 min of intracellular dialysis in the whole-cell configuration
(p = 0.51 and 0.23, respectively;
n = 17). Furthermore, the magnitudes of inhibition and
stimulation were uncorrelated with the initial 1E Ca current density
(r = 0.09; n = 42; p = 0.58 for stimulation; r = 0.16; n = 42;
p = 0.31 for inhibition). Inhibition of 1A and 1B
were similarly independent of initial Ca current density
(r = 0.18; n = 11; p = 0.59 for 1A; r = 0.33; n = 11;
p = 0.38 for 1B). Thus, differences among cells in
Ca channel expression level were not a significant variable in our experiments.
Pertussis toxin eliminates inhibition of 1E without
affecting stimulation
We used pertussis toxin (PTX) to investigate which G-proteins
underlie the inhibition and stimulation of 1E. As shown in Figure
2, pretreatment with PTX (200 ng/ml for
24 hr) nearly abolished the M2 receptor-mediated inhibition of 1E
currents, demonstrating that this inhibition is primarily mediated by
Gi/o proteins (West et al., 1985; Avigan et al., 1992). In contrast,
PTX had no effect on the magnitude of stimulation (Fig. 2C).
The act of Ca currents in PTX-treated cells was 1.1 ± 0.1 msec before and 1.2 ± 0.1 msec during exposure to CCh
(n = 7). Thus, Ca currents recorded from PTX-treated
cells did not exhibit kinetic slowing (Fig. 2B),
consistent with the absence of membrane-delimited, voltage-dependent
inhibition after PTX treatment. Interestingly, in some cells (e.g.,
Fig. 2A) stimulation of 1E reached a peak and then
spontaneously decreased even though CCh was still present. This
behavior was observed, to varying degrees, in both PTX-treated and
control cells (see and compare Figs.
3D,E, 6B).
Although we do not currently understand the mechanism, the spontaneous
decrease in stimulation is unlikely to reflect receptor
desensitization, because inhibition of 1A and 1B was well
maintained during CCh applications of similar duration (Fig.
1C,D). The over-recovery of 1E current amplitude after
CCh washout (Fig. 1A) also argues against receptor
desensitization. In summary, inhibition of 1E involves a
PTX-sensitive G-protein, but stimulation does not. The biphasic,
opposing modulation of 1E therefore requires at least two distinct
signaling pathways that couple to M2 receptors.
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Figure 2.
PTX abolishes M2 receptor-mediated
inhibition of 1E without reducing stimulation. A,
Maximal Ca currents recorded from a PTX-pretreated cell plotted as a
function of time. The horizontal bar indicates
application of CCh (50 µM). Currents were evoked every 5 sec, using the voltage protocol illustrated in B. B, Ca
current waveforms recorded at the times
(points a-c) indicated in A.
C = 22 pF; RS = 1.5 M. File 98O02022. C, Average (± SEM) inhibition and
stimulation in control cells (n = 42) and
PTX-pretreated cells (n = 7; p = 0.27 for stimulation).
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Although native neurotransmitter receptors have been shown to couple to
both PTX-sensitive and PTX-insensitive pathways in neurons (Hay and
Kunze, 1994; Choi and Lovinger, 1996; Kammermeier and Ikeda, 1999), it
is conceivable that M2 receptors couple to the PTX-insensitive pathway
only when they are expressed at higher concentrations than are
endogenous Gi/o proteins. To investigate this possibility, we
decreased the level of receptor expression by including reduced amounts
of M2 receptor plasmid in our transfection mixture. Neither inhibition
(35.0 ± 2.4%; n = 10) nor stimulation (27.4 ± 5.7%; n = 10) of 1E was significantly reduced in
cells transfected with 1/2 the normal amount of receptor plasmid,
suggesting that M2 receptors were in fact expressed at saturating
levels in our experiments. However, in cells transfected with 1/10 the normal amount of receptor plasmid, inhibition was reduced to 16.5 ± 5.7% (n = 10). This ~60% reduction in inhibition
presumably means that the cells' capacity to supply endogenous Gi/o
proteins had not been exceeded. Importantly, stimulation was reduced to a comparable degree in these cells, to 12.9 ± 3.7%
(n = 10). These results indicate that M2 receptors
couple to the PTX-insensitive pathway even when these receptors are
expressed at nonsaturating levels.
We next used cholera toxin (CTX) to explore whether Gs participates
in the stimulation of 1E. CTX produces tonic activation of Gs
that is followed by downregulation of the Gs protein within 8 hr
(Gill and Meren, 1978; Chang and Bourne, 1989). Stimulation of 1E
currents was reduced to 10 ± 2% (n = 10) in
cells exposed to CTX (500 ng/ml for 10-18 hr), compared with 25 ± 2% (n = 42) stimulation in untreated control cells
(p = 0.001). However, CTX also reduced the
inhibition of 1E to 24 ± 2% (n = 10),
compared with 40 ± 1% (n = 42) inhibition in
control cells. Because inhibition of 1E is mediated primarily by
Gi/o (Fig. 2), these results suggest that CTX has additional
effects. As one possibility, CTX may decrease the number of
functionally expressed M2 receptors (MacKenzie and Milligan, 1991). We
conclude that Gs is not a key component of the pathway producing
stimulation of 1E Ca channels.
Modulation of 1E is unaltered by coexpression of Ca channel
subunits
Previous studies have found that G-protein-dependent inhibition
of native neuronal Ca channels is enhanced after depletion of Ca
channel subunits (Campbell et al., 1995). Furthermore, G-protein-mediated inhibition of cloned rat 1A Ca channels
expressed in Xenopus oocytes is decreased by coexpression of
exogenous Ca channel subunits (Bourinet et al., 1996).
Recently, it was reported that coexpression of rat brain 2a subunits
occludes (Qin et al., 1997) or significantly reduces (Qin et al., 1998)
the M2 receptor-mediated inhibition of human 1E Ca channels
expressed in Xenopus oocytes. These and other findings have
suggested that G-proteins and Ca channel subunits compete for
similar binding sites on Ca channel 1 subunits (De Waard et al.,
1997; Zamponi et al., 1997).
To determine whether stimulation of 1E could be antagonized by
coexpression of Ca channel subunits, we compared the modulation of
currents produced by coexpression of 1E and 2 alone with currents
recorded from cells expressing 1E, 2, and either 3 (from
rabbit brain) or 2a (from rat brain). As shown in Figure 3A, the average current
density was significantly higher (87 ± 10 pA/pF;
n = 42) in cells cotransfected with rabbit 3 than in cells cotransfected with rat 2a (21 ± 3 pA/pF;
n = 13). In contrast with this result, Jones et al.
(1998) found that rat 2a and rat 3 were equally effective in
enhancing the current density of the rat 1E. However, in their
experiments the 2 subunit was omitted, and their 1E and subunits were from rat rather than from rabbit. In our experiments,
cells not transfected with an exogenous subunit had an average
1E current density of 19 ± 2 pA/pF (n = 17);
this is an overestimation, however, because these 17 cells were
selected for experiments on the basis of their relatively large Ca
currents. We found that cells transfected with 1E and 2 alone
tended to express either very small or reasonably large Ca current
densities, raising the possibility that some (but not all) HEK293 cells
express endogenous subunits. We found that the current-voltage
(I-V) relationship was unaffected by coexpression of either 2a or 3 (Fig. 3B). In contrast,
several other previous studies have found that subunit coexpression produces a negative shift in the voltage dependence of activation of
1E (Wakamori et al., 1994; Williams et al., 1994; Parent et al.,
1997; Stephens et al., 1997; Jones et al., 1998).
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Figure 3.
Effects of coexpressing Ca channel subunits.
A, Average current densities (left) and
extent of inactivation (right) in cells transfected with
1E and 2 alone () or with 1E and 2 plus 2a or 3
subunits are shown. Data are from currents evoked by depolarizations
from 90 to +30 mV. Inactivation was quantified as the percentage of
peak current remaining at the end of a 500 msec test pulse.
B, Coexpression of 2a or 3 does not significantly
alter the voltage dependence of 1E currents. Each
I-V plot represents normalized, averaged
data from three to five cells in each group. C,
Coexpression of the rat brain 2a subunit slows macroscopic
inactivation. Current amplitudes have been scaled to facilitate
comparison. cell: C = 21 pF;
RS = 2.1 M. File 99129008. 2a cell:
C = 49 pF; RS = 1.8 M. File 99128006. 3 cell: C = 27 pF;
RS = 2.6 M. File 99127009. D, Exogenous Ca channel subunits are not required
for stimulation of 1E. The horizontal bar indicates
CCh application. Currents in a cell transfected with 1E and 2
alone were evoked by depolarizations to +30 mV every 2 sec.
C = 48 pF; RS = 4.5 M. File 98701008. E, Coexpression of the rat
brain 2a subunit does not prevent inhibition or stimulation of the
rabbit 1E Ca channel. Currents in a cell transfected with 1E,
2, and rat brain 2a were evoked every 2 sec.
C = 39 pF; RS = 3.1 M. File 98619010. F, The average magnitudes of
inhibition and stimulation of 1E are unaffected by coexpression of
rat brain 2a or rabbit brain 3 subunits.
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Coexpression of rat brain 2a significantly slowed macroscopic
inactivation (Fig. 3C). Inactivation was quantified by
measuring the percentage of current remaining at the end of a 500 msec
depolarization to +30 mV (Fig. 3A). This percentage was
28.2 ± 5.1% for 2a cells (n = 7), 6.0 ± 1.1% for 3 cells (n = 7), and 11.4 ± 3.7%
for cells not transfected with a subunit (n = 7).
These changes in current density and inactivation rate demonstrate that
both 2a and 3 were functionally expressed.
Biphasic modulation of 1E did not require coexpression of an
exogenous subunit (Fig. 3D). Furthermore, coexpression
of rat brain 2a neither occluded nor reduced inhibition of 1E
(Fig. 3E). In fact, the average magnitudes of inhibition and
stimulation were not significantly altered by coexpression of either
2a or 3 (Fig. 3F). These findings differ
markedly from those obtained by Qin et al. (1997) for the human 1E
Ca channel. However, they agree with recent results obtained by Page et
al. (1998) for rat 1E. Together with the latter study, our
observations seem inconsistent with the hypothesis that Ca channel subunits compete with G subunits for binding sites on neuronal Ca channels.
Stimulation of 1E involves phosphorylation
The relatively slow time course of stimulation (Fig.
1B) suggested the involvement of a cytosolic
signaling pathway. The rabbit 1E subunit contains several
phosphorylation consensus sites (Niidome et al., 1992), and 1E has
been demonstrated to be a substrate in vitro for
phosphorylation by cAMP-dependent protein kinase (PKA), protein kinase
C (PKC), cGMP-dependent protein kinase (PKG), and CaMKII
(Yokoyama et al., 1995). To explore whether stimulation of 1E
requires phosphorylation, we exposed cells to staurosporine, a
broad-spectrum kinase inhibitor. As shown in Figure
4, stimulation was completely blocked by
1 µM staurosporine, whereas inhibition was
unaffected. Stimulation was also substantially reduced (to 6.1 ± 1.6%; n = 4) by a much lower concentration of
staurosporine (50 nM), consistent with a specific
action of this compound on protein kinases. Application of the vehicle
(DMSO) alone had no effect (Fig. 4B). To determine
further the involvement of phosphorylation in stimulation of 1E, we
dialyzed cells with the nonhydrolyzable ATP analog
5'-adenylylimidodiphosphate (AMP-PNP; 5 mM) for
>5 min before applying CCh. As shown in Figure 4C,
stimulation was significantly reduced (p = 0.004) in cells dialyzed with AMP-PNP, whereas inhibition was
unaffected (Fig. 4D). Together these results suggest
that stimulation of 1E involves phosphorylation by a protein
kinase.
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Figure 4.
Stimulation of 1E involves phosphorylation. Ca
currents were evoked every 2-10 sec by step depolarizations to +30 mV.
A, Staurosporine (1 µM) blocks stimulation
of 1E without affecting inhibition. The staurosporine solution
contained 0.05% DMSO. The horizontal bar indicates CCh
application. C = 11 pF;
RS = 4.5 M. File 98625008. B, DMSO alone (0.05%) has no effect.
C = 48 pF; RS = 3.6 M. File 98624003. C, Stimulation is reduced by
intracellular dialysis with 5 mM AMP-PNP.
C = 36 pF; RS = 2.6 M. File 98903001. D, Summary of results.
Control data were from cells exposed to 0.05% DMSO. OA,
Okadaic acid (100 nM); Stauros,
staurosporine.
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If stimulation involves phosphorylation, then recovery from stimulation
should involve dephosphorylation. To explore this issue, we exposed
cells to 100 nM okadaic acid for at least 2 hr before and
throughout the experiments. As summarized in Figure 4D, okadaic acid did not change the magnitude of
stimulation. Okadaic acid did not prevent recovery from stimulation
(data not shown), suggesting that phosphatases 1 and 2A are not
required for this event. Unfortunately, we were unable to determine
whether okadaic acid altered the time course or extent of recovery.
Stimulation of 1E does not involve PKA, PKC, or PKG
M2 muscarinic acetylcholine receptors couple efficiently to Gi,
and activation of these receptors can inhibit adenylyl cyclase and
thereby reduce the intracellular concentration of cAMP (Ashkenazi et
al., 1987; Peralta et al., 1988). To investigate the possibility that
stimulation of 1E results, either directly or indirectly, from a
decline in intracellular cAMP, we dialyzed cells with a pipette
solution containing 5 mM cAMP for at least 5 min before applying CCh. As shown in Figure
5A, this treatment had no
effect on the magnitude of stimulation. We also found that stimulation was unaffected by dialyzing cells with 100 µM
protein kinase inhibitor (6-22) amide, a specific peptide
inhibitor of PKA (n = 3; data not shown). These results
suggest that changes in intracellular cAMP or phosphorylation by PKA do
not account for stimulation of 1E.
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Figure 5.
Stimulation of 1E does not involve PKA,
IP3, PKC, or PKG. Ca currents were evoked every
2-10 sec by depolarizations to +30 mV. Cells were dialyzed with cAMP,
IP3, PKC 19-36, or cGMP for 5-10 min before
applying CCh (indicated by solid horizontal bar).
A, Intracellular cAMP (5 mM) does not reduce
stimulation. C = 17 pF;
RS = 2.8 M. File 98731007. B, Intracellular IP3 does not reduce
stimulation. C = 19 pF;
RS = 3.0 M. File 99121011. C, The phorbol ester PMA (100 nM) does
not reduce stimulation. C = 18 pF;
RS = 2.6 M. File 98820015. D, Effects of the inactive -phorbol (100 nM) are shown. C = 15 pF;
RS = 4.2 M. File 98908001. E, Intracellular application of PKC 19-36 (100 µM), a pseudosubstrate inhibitor of PKC, does not
reduce stimulation. C = 11 pF;
RS = 3.1 M. File 98626003. F, Intracellular cGMP (5 mM) does not
reduce stimulation. C = 37 pF;
RS = 4.6 M. File 98730022. G, Bath application of membrane-permeant 8-Br-cGMP
(indicated by hatched horizontal bar; 100 µM) does not reduce stimulation.
C = 19 pF; RS = 2.0 M. File 98925012. H, Summary of results
(p = 0.62, ANOVA).
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M2 receptors weakly stimulate the production of phosphoinositides
(Ashkenazi et al., 1987), suggesting that these receptors may also
couple to Gq proteins, although with lower efficiency than they
couple to Gi/o (Peralta et al., 1988). In agreement with this
possibility, Berstein et al. (1992) observed that M2 receptors
stimulate GTP--S binding by Gq reconstituted into lipid vesicles,
although M2 receptors are only 10% as effective as M1 receptors in
this regard. Classically, Gq subunits stimulate phospholipase C1,
resulting in the production of inositol trisphosphate and
diacylglycerol (DAG). Inclusion of D-myo-inositol
1,4,5-trisphosphate (IP3; 100 µM)
in the standard 10 mM EGTA-containing pipette solution had
no effect (Fig. 5B), suggesting that signaling by
IP3 is not involved in producing stimulation of
1E.
Some forms of PKC are activated by DAG. To investigate the potential
involvement of PKC in producing stimulation of 1E, we exposed cells
to 100 nM phorbol 12-myristate 13-acetate (PMA) before and
during CCh application. As illustrated in Figure 5C, Ca
current amplitudes slowly increased during PMA exposure, presumably reflecting the PKC-dependent phosphorylation of 1E channels or associated proteins. In contrast, the inactive 4-phorbol produced a
slight decrease in Ca current amplitudes (Fig. 5D). These
results confirm previously demonstrated effects of PMA on 1E Ca
channels (Stea et al., 1995). Despite its ability to increase baseline 1E currents, PMA did not occlude stimulation of 1E by CCh (Fig. 5H). Interestingly, PMA did reduce the magnitude of
1E inhibition to 28.5 ± 2.7% (n = 6),
compared with 40.0 ± 1.4% inhibition in control cells
(n = 42). In additional experiments, we dialyzed cells
with PKC 19-36, a pseudosubstrate peptide inhibitor of PKC, for >5
min before applying CCh. As shown in Figure 5E, the PKC 19-36 peptide had no effect on stimulation. Inhibition in cells dialyzed with PKC 19-36 was also identical (40.2 ± 6.0%;
n = 6) to that in control cells. Thus, PKC-dependent
phosphorylation does not seem to be involved in the M2
receptor-mediated stimulation of 1E.
We next examined whether stimulation of 1E involves PKG.
Intracellular dialysis with cGMP (5 mM) did not reduce the
magnitude of stimulation (Fig. 5F). Application of
8-bromo-cGMP (8-Br-cGMP; 100 µM), a
membrane-permeant, hydrolysis-resistant analog of cGMP, consistently
produced a slow decrease in the amplitude of 1E currents (Fig.
5G). However, 8-Br-cGMP failed to alter the magnitude of
CCh-induced stimulation (Fig. 5H). In summary, these
experiments with activators and inhibitors of various protein kinases
suggest that PKA, PKC, and PKG are not responsible for the M2
receptor-mediated stimulation of 1E.
Stimulation of 1E does not involve tyrosine kinases or
phosphoinositide 3-kinases
Previous studies have shown that G-protein-coupled receptors can
modulate ion channels via activation of tyrosine kinases (Huang et al.,
1993; Diversé-Pierluissi et al., 1997; Felsch et al., 1998). We
used genistein, a broad-spectrum tyrosine kinase inhibitor, to examine
whether tyrosine kinase-dependent phosphorylation underlies
stimulation of 1E. As shown in Figure
6A, genistein caused a
substantial inhibition of 1E currents under control conditions. This
effect of genistein may result from inhibition of basally active
tyrosine kinases or direct block of 1E channels. In support of the
latter possibility, genistein can directly block voltage-gated Na
channels (Paillart et al., 1997), GABAA channels (Huang et al., 1999), and T-type Ca channels (U. Meza and B. Adams, unpublished observations). However, the fact that daidzein (a weakly
active genistein analog) produced a much smaller decrease in 1E
currents than did genistein (Fig. 6B) is consistent
with inhibition of basally active tyrosine kinases. As summarized in Figure 6C, neither genistein nor daidzein significantly
altered the CCh-induced modulation of 1E currents. Intracellular
application of genistein (100 µM) through the
patch pipette, either alone or in combination with external genistein
application, also failed to alter the inhibition or stimulation of
1E (data not shown). Although these experiments are not exhaustive,
they indicate that genistein-sensitive tyrosine kinases are not
responsible for M2 receptor-mediated stimulation of 1E.
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Figure 6.
Stimulation of 1E does not involve tyrosine
kinases or phosphoinositide 3-kinases. A, Genistein
(hatched horizontal bar; 100 µM) inhibits
1E current but does not prevent stimulation. The solid
horizontal bar indicates CCh application. C = 52 pF; RS = 2.5 M. File 98814002. B, Daidzein (100 µM) produces less
inhibition than does genistein. C = 27 pF;
RS = 2.1 M. File 98911030. C, Summary of results, including data from cells exposed to
200 nM wortmannin for at least 2 hr before and during
experiments.
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Recent experiments by Viard et al. (1999) have shown that vascular
L-type Ca channels are stimulated via a pathway involving G-activated phosphoinositide 3-kinases (PI3-K). We used
wortmannin, a cell-permeant, irreversible PI3-K inhibitor, to evaluate
the potential involvement of these kinases in stimulation of 1E. Cells were exposed to 200 nM wortmannin for at least 2 hr
before and throughout the experiments. Inhibition and stimulation in wortmannin-treated cells were 36.0 ± 2.3% (n = 10) and 21.5 ± 4.3% (n = 10), respectively, not
significantly different from that of control cells (Fig.
6C). Thus, wortmannin-sensitive PI3-kinases do not appear to
be responsible for stimulation of 1E.
Stimulation of 1E does not require a Ca signal
In rat sympathetic ganglion neurons, activation of endogenous
muscarinic receptors produces biphasic (i.e., fast and slow) inhibition
of N-type Ca channels. The fast inhibition occurs via a
membrane-delimited pathway, whereas the slow inhibition occurs via a
cytosolic pathway that does not seem to involve PKA, PKC, or PKG
(Bernheim et al., 1991). Inhibition of N-type channels via the slow
pathway is blocked by high intracellular concentrations of BAPTA or
EGTA (Beech et al., 1991), suggesting that this slow pathway involves a
Ca signal. If stimulation of 1E also involves a Ca signal, then this
signal might be increased, and stimulation consequently enhanced, by
reducing intracellular Ca buffering. However, we found that both
inhibition and stimulation were significantly reduced (to 27.1 ± 2.4 and 14.3 ± 2.7%, respectively; n = 10) when
the pipette solution contained a reduced concentration (0.1 mM) of EGTA (Fig.
7A). Similar results were
obtained using a pipette solution containing 0.1 mM BAPTA (25.2 ± 2.3% inhibition and
12.8 ± 2.2% stimulation; n = 10). Thus, reducing
intracellular Ca buffering clearly did not enhance stimulation. The
decreased modulation of 1E channels with 0.1 mM intracellular EGTA or BAPTA is unexplained and
is at odds with the finding of Beech et al. (1991) that modulation of
native N-type channels is greatest in the presence of low intracellular concentrations of Ca buffers.
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Figure 7.
Stimulation does not require a Ca signal.
A, Average magnitudes of inhibition and stimulation with
different concentrations of Ca buffers in the pipette solution are
shown. The pipette solutions contained (in mM): 10 EGTA,
0.1 EGTA, 0.1 BAPTA, 20 BAPTA, or 20 BAPTA plus 10 Ca.
B, Stimulation of 1E is not prevented by 20 mM intracellular BAPTA. C = 14 pF;
RS = 2.3 M. File 99106001. C, Stimulation of 1E does not require Ca influx. For
these experiments, the bath solution initially contained 40 mM Ca. Directly before CCh application (solid
horizontal bar), the bath solution was switched to one
containing 40 mM Ba (hatched horizontal
bar). C = 30 pF;
RS = 4.4 M. File 98O09014.
Cells were dialyzed for >5 min in the whole-cell configuration with
BAPTA-containing pipette solutions before applying CCh. Currents were
evoked every 5 sec (B) or 2 sec
(C) by depolarizations to +30 mV.
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Our standard pipette solution contained 10 mM EGTA, which
is expected to produce effective steady-state buffering of
intracellular Ca. However, EGTA has a relatively slow on-rate and hence
may not prevent rapid Ca transients. To examine whether stimulation of
1E involves a rapid Ca signal, we used the fast Ca buffer BAPTA. As
shown in Figure 7B, stimulation of 1E was not prevented by 20 mM intracellular BAPTA. As was found for
0.1 mM EGTA and BAPTA, both inhibition and
stimulation were reduced to similar degrees by 20 mM BAPTA (Fig. 7A). To determine
whether these effects of high BAPTA concentration stemmed from
buffering intracellular Ca at extremely low levels (cf. Cruzblanca et
al., 1998), we used a pipette solution containing 20 mM BAPTA plus 10 mM added
Ca. This solution is predicted to have a free Ca concentration of ~140 nM (Beech et al., 1991), very close to the
resting cytoplasmic Ca concentration measured in HEK293 cells (Tong et
al., 1999). As summarized in Figure 7A, inhibition and
stimulation of 1E were similarly reduced by 20 mM BAPTA even in the presence of physiological
free Ca. These results are consistent with the previously suggested
(Beech et al., 1991) possibility that BAPTA has intracellular effects
unrelated to its Ca-chelating properties.
To test whether influx of extracellular Ca is required for stimulation
of 1E, we substituted equimolar Ba for Ca as the charge carrier. For
these experiments, a nominally Ca-free pipette solution (20 mM BAPTA and no added Ca) was used. As shown in Figure
7C, Ba currents through 1E channels exhibited biphasic,
opposing modulation. The magnitude of stimulation for Ba currents was
14.3 ± 1.3% (n = 6), similar to stimulation of
Ca currents (11.8 ± 1.9%; n = 15) recorded using
the same pipette solution. In summary, these experiments with BAPTA,
EGTA, and Ba suggest that stimulation of 1E does not require Ca
influx, a transient rise in intracellular Ca concentration, or the
participation of a Ca-activated signaling molecule (e.g., calmodulin,
calcineurin, or CaM kinases).
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DISCUSSION |
We have demonstrated that 1E Ca channels are simultaneously
inhibited and stimulated during activation of M2 muscarinic
acetylcholine receptors. Inhibition has a relatively fast onset and is
associated with kinetic slowing, suggesting that it occurs via a
membrane-delimited pathway. In contrast, stimulation is considerably
slower in onset and seems to require phosphorylation, suggesting that
it occurs via a cytosolic, kinase-dependent pathway. Kinetic slowing is maintained during stimulation, and after CCh washout, both kinetic slowing and inhibition of current amplitude are rapidly relieved. The
over-recovery of current amplitude after CCh washout is approximately equal to the magnitude of inhibition, indicating that inhibition is
maintained at a relatively constant level during stimulation. These
observations demonstrate that inhibition and stimulation of 1E are
separate events, with stimulation superimposed on inhibition.
Inhibition and stimulation involve at least two distinct signaling
pathways coupled to M2 receptors, because inhibition depends on
PTX-sensitive G-proteins whereas stimulation does not. This dual
coupling occurs even when M2 receptors are expressed at nonsaturating levels. The coupling of M2 receptors to more than one pathway is not
likely to be an artifact of heterologous expression, because endogenous
metabotropic glutamate receptors have also been shown to couple to both
PTX-sensitive and PTX-insensitive pathways in neurons (Hay and Kunze,
1994; Choi and Lovinger, 1996; Kammermeier and Ikeda, 1999). Previous
studies have found that HEK293 cells express Gi(1-3), Go, Gq,
and Gs proteins (Law et al., 1993; Kim et al., 1994; Offermanns et
al., 1994; Yamauchi et al., 1999). When expressed in HEK293 cells, M2
receptors are thought to couple to Gi/o proteins with high
efficiency and possibly also to Gq proteins with much lower
efficiency (Ashkenazi et al., 1987; Peralta et al., 1988). Our
experiments with PTX and CTX indicate that Gi/o or Gs are not
responsible for stimulating 1E. Thus, by elimination Gq seems the
most likely candidate. However, Gq is classically thought to
activate phospholipases, resulting in the liberation of
IP3 and DAG, which trigger intracellular Ca release and activation of PKC, respectively. Because our results indicate that stimulation of 1E does not involve signaling by IP3, PKC, or Ca, it is currently unclear how
Gq might produce stimulation. Potentially, dimers released
from Gq could activate small GTPases (e.g., Ras) that in turn could
activate MAP kinases (Crespo et al., 1994), and MAP kinase-dependent
phosphorylation might directly or indirectly produce stimulation of
1E. However, MAP kinases are activated by phorbol esters (Dulin et
al., 1999; Zhang et al., 1999), and we found that stimulation was
unaltered by PMA (Fig. 5). These considerations suggest that MAP
kinases are unlikely to be responsible for stimulating 1E. Our
experiments additionally suggest that stimulation does not involve
phosphorylation by tyrosine kinases or PI3-kinases (Fig. 6).
Membrane-delimited inhibition is hypothesized to result from direct
binding of G subunits to neuronal 1A, 1B, and 1E subunits [De Waard et al. (1997); Zamponi et al. (1997); but see Diversé-Pierluissi et al. (1997)]. If this hypothesis is
correct, then our data suggest that G subunits remain bound to
1E during stimulation. However, because stimulation can occur in the
absence of inhibition (Fig. 2), G binding to 1E may not be a
prerequisite for stimulation. Conversely, if stimulation involves
phosphorylation of 1E itself, then such phosphorylation must not
reduce G binding or counteract its effects on channel gating. For
1A and 1B Ca channels, PKC-dependent phosphorylation of specific
amino acids within the I-II loop reduces binding of G subunits
and thereby antagonizes G-mediated channel inhibition (De Waard
et al., 1997; Zamponi et al., 1997). Reduction of N-type Ca channel
inhibition can also occur via PKC-dependent phosphorylation of
neurotransmitter receptors (García et al., 1998a). In both
cases, PKC-dependent phosphorylation actually decreases the
G-mediated inhibition of 1A and 1B. These two types of
"cross-talk" between kinase-dependent and G-protein-dependent
pathways are distinct from the biphasic, opposing modulation of 1E
described here, in which stimulation develops in the continued presence
of inhibition and does not substantially reduce the extent of inhibition.
For N-type Ca channels, the first latency of single-channel opening is
increased by G-protein-dependent, membrane-delimited inhibition
(Carabelli et al., 1996; Patil et al., 1996). If the same molecular
mechanism applies to G-protein-inhibited 1E Ca channels, then the
persistence of kinetic slowing during the secondary stimulation phase
predicts that first latencies remain long during stimulation. Our
results therefore suggest that stimulation of 1E reflects decreased
single-channel closed time, increased channel open time, or an increase
in the number of functional channels (Yang and Tsien, 1993). Further
experiments using single-channel recordings will be necessary to
discriminate among these
TOP
ABSTRACT
INTRODUCTION
